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Luftgestützte Messung von HO$_{x}$-Radikalkonzentrationen mittels Laser-induzierter Fluoreszenz auf einem Zeppelin NT: Untersuchung der atmosphärischen Oxidationsstärke der unteren Troposphäre



2014
Forschungszentrum Jülich GmbH Zentralbibliothek, Verlag Jülich
ISBN: 978-3-89336-981-2

Seminar, Universität WuppertalUniversität Wuppertal, Germany, Jülich : Forschungszentrum Jülich GmbH Zentralbibliothek, Verlag, Schriften des Forschungszentrums Jülich, Reihe Energie & Umwelt / Energy & Environment 224, 205 S. () = Universität Wuppertal, Diss., 2014

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Abstract: The OH radical is the major atmospheric oxidant that dominates the photochemical degradationof trace gases and pollutants in the atmosphere. The consumed OH can be recycledthrough the HO$_{2}$ radical by reacting with NO, thereby forming ozone. Thus, OH and HO$_{2}$ are ideal parameter in order to test the current understanding of the atmospheric degradation of trace gases. In this work, an instrument for the measurement of OH and HO$_{2}$ radicals by laser induced fluorescence was developed and deployed on board a Zeppelin NT. The measurements presented here were conducted in July and August 2012 in the region Emilia Romagna in Northern Italy. The measurement platform Zeppelin NT allowed the observation of a comprehensive set of chemical and physical parameter within the lower troposphere between 75 − 900m above ground. During the measurement flights, strong trace gas gradients were observed in the early morning that could be explained by the layering within the lanetary Boundary Layer. Typically, low trace gas concentrations were found in the residual layer in high altitudes whereas the highest OH reactivities up to 10 s$^{−1}$ and NO$_{x}$ mixing ratios up to 10 ppbv were observed in the mixed layer which is strongly influenced by ground emissions. The linear correlation between observed OH and j(O$^{1}$D) with a slope of 4.4 × 10$^{11}$ cm$^{−3}$s is comparable to other field measurements in continental regions. Additionally, the observed OH depends nonlinearly on NO$_{x}$ resulting in enhanced mean OH concentrations by a factor of 2 for NO$_{x}$ mixing ratios between 1.5 and 2.0 ppbv. Observed mean HO$_{2}$ concentrations in air masses with [NO] < 250 pptv were up to a factor of 5 higher than in air masses with [NO] > 1 ppbv. For the first time, this HO$_{x}$ dependency on NO$_{x}$ was observed locally when crossing vertical and horizontal NO$_{x}$ gradients. Box model calculations based on the Regional Atmospheric Chemistry Mechanism reproduce the measured OH for [NO$_{x}$] < 3 ppbv. For higher NO$_{x}$ mixing ratios, the model overestimates OH for more than 50% of the data points. The model predicts HO$_{2}$ within the uncertainty of the measurements and the model. The prediction for OH could be improved by implementing a newly proposed gas phase machanism forming HONO (Li et al., 2014). The analysis of the HO$_{x}$ data does not hint at a significant NO independent, non-classical OH-recycling during the measurement flights performed in Italy.


Note: Universität Wuppertal, Diss., 2014

Contributing Institute(s):
  1. Troposphäre (IEK-8)
Research Program(s):
  1. 233 - Trace gas and aerosol processes in the troposphere (POF2-233) (POF2-233)

Appears in the scientific report 2014
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 Record created 2014-08-15, last modified 2021-01-29


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